NO814061L - CONTACT DEVICE - Google Patents

Abstract

A contact arrangement includes an elongated striker reciprocable in direction of its elongation and a pair of movable contacts moved by the striker and cooperating with adjacent stationary contacts so that during reciprocation of the striker between two end positions one of said movable contacts engages the stationary contact adjacent thereto while the other movable contact is spaced from the adjacent stationary contact, and vice versa. In order to obtain during the reciprocation of the striker up to the moment of switching the contacts a high contact pressure, the striker is provided with a guide extending transverse to its reciprocation direction for a movable guide body. The movable guide body is mounted on one end of a link member the other end of which is articulately engaged with an angle lever in the region of the knee of the latter. A tension spring is connected at one end to the movable guide body and at the other end to one arm of the angle lever, the other arm of which is pivotally mounted on said support. A stationary guide body is coordinated with the movable guide body and the arrangement is made in such a manner that during the switching movement the movable guide body first moves in one direction along one face of the stationary guide body and then in the opposite direction along an opposite face of the stationary guide body.

Description

The invention relates to a contact device which comprises

a longitudinally displaceable bumper and from this influen-

bare, movable contact pieces that interact with fixed contact pieces to form openers and/or closers.

Contact devices of the above type are known in

several different constructions and in different areas of application. As an example, there are known relays or thermal overcurrent releases for which the present invention finds preferred application. However, the invention can in principle be applied to all contact devices in which creeping or slow movements can occur to influence the contact device and in which a shock-like switching is nevertheless desired and must be effected.

In the case of the hitherto known contact devices, the contact pressure between the mutually touching, movable and fixed contact pieces depends on the maneuver stroke length or of the switching path, i.e. the contact pressure decreases during the switching path until the value zero is reached, i.e. practically no contact pressure is present anymore, and only then does the switching occur while opening the contact. This results in significant disadvantages, in particular an uncertain contact formation and, in several operating conditions, no sufficient vibration safety.

The purpose of the invention, on the other hand, is to provide

a contact device by which a safe contact formation is ensured and which above all is vibration-proof also in automatic or mechanical impact or maneuvering.

The above purpose is achieved according to the invention in that the pusher exhibits a guide for a movable guide body running across its direction of displacement, that the guide body is placed on a connecting link, that the connecting link engages in a joint manner in the area of the knee of an angle piece, that between the guide body and the angle piece's one leg is provided with a tension spring, that the angle piece is pivotally stored with the help of the other leg, and

that the movable guide body is assigned to a fixed guide body in such a way and the device is

arranged in such a way that the movable guide body during the switching path in one direction is guided along one

side and in the other direction. is guided along the other side of the stationary guide body.

The advantages obtained with the help of the invention lie mainly in the fact that a high contact pressure is maintained during the maneuver stroke length or the switching path until immediately before the switching. This results in a secure contact formation. Furthermore, the contact device is vibration-proof under all operating conditions, especially also in automatic or mechanical maneuvering. In this way, the contact device according to the invention is also suitable for electrical low voltages of, for example, 24 V.

Advantageous embodiments of the invention appear from the subclaims.

The invention shall be described in more detail below

in connection with design examples with reference to the drawings, where fig. 1 shows a diagram in which the progress of the contact pressure over the switching path in a contact device according to the known technique is visualized, fig. 2 shows a diagram according to fig. 1 which shows the progress of the contact pressure over the switching path in a contact device according to the invention, fig. 3' shows a schematic representation of an embodiment of a contact device in an initial operating position, fig. 4 shows a contact device according to fig. 3 in an operating position before switching, fig. 5 shows a contact device according to fig. 3 in another operating position after the switching, fig. 6 again shows the contact device according to fig. 3 in an intermediate operating position before the feedback,

fig. 7 shows the contact device according to fig. 3 in a second operating position after the feedback, corresponding to the initial position according to fig. 3, and fig. 8 shows a ground plan of a contact device enlarged several times, i.e. an embodiment example in form.

Fig. 1 refers to the known technique and

more precisely to the progress of the contact pressure during the switching path. The figure shows the contact pressures in Newtons

along the vertical coordinate 1, while the switching path in millimeters is indicated along the horizontal coordinate 2. In the case of a contact device in a cold state, for example a cold relay, it is assumed in this example that the contact pressure between a movable and a fixed contact piece in the switched-on state amounts to itself to 0.5 N., more specifically in accordance with line 3. In the operating state, the contact pressure has dropped to approx. half. During the switching path, the contact pressure drops further in accordance with line 7 and reaches the value zero after a switching path of, for example, 0.7 mm at the switching point 4. The opening of the contact (opens) thus occurs under a very small contact pressure that goes towards zero. After the opening, a contact pressure 5 occurs to a shutter. During the backward switching path according to the dashed line 8, this contact pressure also falls again to a value of zero until the shutter's feedback point 6. During the switching, the contact pressure 9 to the opener occurs again. These contact pressure changes are repeated during the forward or backward switching path 10. Fig. 2 clearly illustrates the progress of the contact pressure in a contact device according to the invention. It appears that the contact pressure at the contact device in a cold state, in accordance with line 3, remains the same across the switching path 10 up to the opener's switching point 13. After switching, the shutter's contact pressure 12 is obtained, which corresponds to the previous contact pressure 11 of the opener. Here, too, the contact pressure 12 over the returning switching path according to the dashed line remains the same up to the switching point 14, and after the switching the opener's contact pressure 15 occurs again, which corresponds to the contact pressure 11 in the switching point 13. Fig. 3-7 illustrate the construction principle for a contact device according to the invention with a longitudinally displaceable pusher (German: Stossel) 34 which is held in place in guides 35, 36. This pusher 34 serves to influence or maneuver movable contact pieces 39 or 40

which cooperates with fixed contact pieces 37, respectively 38.

In the operating position according to fig. 3, from which it must first be assumed, the contact pieces 37, 39 produce a shutter and the contact pieces 38, 40 an opener.

On both sides of a movable guide body 28, the pusher 34 has a guide 32, 33 running across its direction of displacement. This guide body 28, for example in the form of a small block, is placed at one end of a coupling or connecting link 27 which in turn with the other end in the joint manner attacks in the area of the knee 18

to a right angle. The angle piece mainly consists of two legs 16 and 17 standing at right angles to each other, which in the area of the knee 18 are rigidly connected to each other.

A tension spring 31 is arranged between the guide body 28 and the outer end of one leg 17 of the angle piece. The pivot point of the tension spring at the outer end of the leg 17 is denoted by the reference number 30. The angle piece is pivotally supported by means of the other leg 16 and more specifically at its outer end. The pivot axis for the fixed bearing is designated with the reference number 19.

As can be seen from the drawings, a stationary guide body 29 is assigned to the movable guide body 28 in such a way, and otherwise with such a design and arrangement of the components described above, that the movable guide body 28 during the switching path in one direction is led along one side and in the other direction is led along the other side of the fixed guide body 29.

The tension spring 31 is arranged in such a way between the guide body 28 and the joint point 30 for the leg 17 of the angle piece that the central axis of the spring with the center line of the leg 1.7 and the connecting link 27 form approximately equal-sized, obtuse-angled triangles in the two end positions of the switching path according to fig. 3 and 7 on one side and fig. 5 on the other hand.

On the angle piece, and then appropriately on the leg

16, a maneuvering weight arm or maneuvering lever 20 attacks by means of a connecting link 21 attached in an articulated manner. The joints at the ends of the connecting link 21 are provided with the reference numbers 22 and 23. On the angle piece, and then, expediently also on the leg 16, it attacks furthermore, a return or return spring 24 which, depending on the side device, can be designed as a compression spring or tension spring. The return spring 24 first rests against a support 25 and is secondly fixed in a joint point 26 on the leg 16. The movable contact pieces. 39, 40. are placed on springs, preferably on leaf springs, 41, 42 which in turn are fixed in holders 43, 44 with suitable power line connections.

The operation of the contact device described above is basically as follows: The starting point is the contact device's operating position according to fig. 3. In this initial position, the pressure of the return spring 24 causes an oscillation of the angle piece with the legs 16, 17, and further of the maneuvering lever 20 with the connecting link 21 and of the connecting link 27 with the movable guide body 28, to the left end position which is limited by means of stops . The tension spring 31 runs here under the knee 18 of the angle piece and produces a force component parallel to the displacement direction of the pusher 3 4, so that the movable guide body 28, which is held in place in the guide 32, 33, presses the pusher 34 downwards, so that the contact between the contact pieces 38, 40 is closed and the contact between the contact pieces 37, 39 is opened. When. the maneuvering lever 20 is now pressed to the right in the direction of the drawn arrow, the angle piece is rotated clockwise about the pivot axis 19 and the joint point 30 of the traction spring 31 moves obliquely upwards in the direction of the arrow 45. The return spring 24 is compressed and the movable guide body 28 slides with a vertical the image plane outside the guide 32, 33 extended part along the underside of the fixed guide body 29 which is otherwise arranged so that it does not hinder the movement of the guide 32, 33. While the movable guide body 28 slides past the fixed guide body 29, an unintentional , too early switching does not occur, and the contact pressure exerted by the leaf spring 42 between the contact pieces 38 and 40 remains maintained unchanged. With the help of the angle piece's pivoting movement about the pivot axis 19, the tension spring 32 achieves

finally a position that goes past the middle position according to fig. 4, i.e. the tension spring 31 extends on the upper side of the knee 18 of the angle piece. This results in an oppositely directed force component, namely in the upward direction, which, however, can only be felt when the movable guide body 28 has been moved so far to the right that it is released of the stationary guide body 29. At this moment, an impact-like switching takes place, i.e. an opening of the contact pieces 38, 40 and a closing of the contact pieces 37, 39. The pusher 34 has then shifted upwards in accordance with fig. 5. When the maneuvering lever 20 is now released or released, the return spring 24 presses the angle piece again towards the starting position in a clockwise direction, whereby the movable guide body 28 now slides along the upper side of the stationary guide body 29 until the middle position according to fig. 6 is exceeded, so that a downward force component appears again and, due to the tension spring 31, the movable guide body 28 acts together with the guide 32, 33

and with the pusher 34 in an impact-like manner is brought to the position according to fig. 7. Thus, the original position according to fig. 3 again achieved. It should also be noted that the one in fig. 2 switching path shown is proportional to the displacement path of the movable guide body 28 in the guide 32, 33. It will be clear that the two-sided displacement movement of the pusher 34 is limited by means of stops not shown.

That in fig. 8 schematically produced example of a contact device according to the invention is based on the same principle that has been described above on the basis of fig. 3-7. In a housing 46, which can be closed by a lid not shown or the like, an angle piece 47 with two legs running at right angles to each other is supported on a pivot axis. The tension spring 50 attacks firstly at a joint point 49 and secondly on the movable guide body 51. The movable guide body 51 is held in place in a guide 62 extending across the displacement direction of the pusher 59.

The fixed guide body is provided with the reference number 52. The connecting or coupling link 53 engages in a bearing 54 which is, for example, produced as a notch or an incision. The pusher 59 has a downwardly extended arm 60 which cooperates with the U-shaped leaf spring 76 of the movable contact piece 77. In a similar way, an upwardly extending arm 61 of the pusher affects the U-shaped bent leaf spring 70 of the movable contact piece 71. The pusher 59 can also be provided with a further extension piece 63 extending across its direction of displacement which can for example reach a viewing window 64 arranged on the front side, so that the current operating position of the contact device can be identified from the outside.

In fig. 8 shows the operating position corresponding to fig. 5, i.e. the tension spring 50 forms with its central axis an obtuse-angled triangle together with the center lines 55, 56 for one leg of the angle piece 47 and for the coupling joint 53. The angle piece 47 is held in place in its swing area between stops 57 and 58, as the stop 57 is secured on a bolt 95.

The pusher 59 is appropriately guided on both sides between guide pieces 65, 66. A return spring 67 also engages the angle piece 47 here. This return spring is provided with the peculiarity that its one end is adjustably placed in an internal thread in a return spring holder 68. The inner thread is appropriate here with regard to the thread grooves adapted to the profile of the return spring coils. The spring end 69 is

rectilinearly bent, so that it runs diagonally with respect to the last feather turn. Thereby, the return spring can be adjusted by means of a simple turn and then at this end attack with a suitable tool.

Opposite the movable contact pieces 71 and 77 here too are fixed contact pieces 72 and 78, which are led to regular power connections 75 and 80 by means of power connection rails 73 and 79, respectively. The U-shaped bent, current-conducting leaf springs 70, 76 are also extended to power connections 74 and 81.

On the angle piece 47. also attacks here, as described in connection with fig. 3-7, a control lever 86,

and more specifically, during intermediate coupling of a connecting link 83 whose joint point on the angle piece is provided with the reference number 82 and whose joint point on the operating lever 86 is provided with the reference number 85. The connecting link 83 is advantageously provided with a spring 84, in the present embodiment with a tension spring, which causes a damping of the transmission of coupling forces.

The design example according to fig. 8 also exhibits a further peculiarity, namely that the operating lever 86 cooperates with a compensating bimetal 89, 90. The compensating bimetal is advantageously designed with an angular shape and at the angularly bent place held pivotably in place in a holder. The holder consists, for example, of a cylindrical pin 91 and a counterpart 92 between which a slot is arranged for inserting the compensating bimetal. The compensating bimetal rests with one leg 89 against one end 88 of the maneuvering lever 86 and with the other leg 90 against an adjustment device which can for example consist of a bolt 93 with a thread and an adjustment wheel 94. The compensating bimetal together with the adjustment device allows a sensitive setting of the operating lever 86 by automatic or mechanical operation of the contact device. It is easy to realize that the leg 89 of the compensating bimetal by screwing down the bolt 93 with its lower end in fig. 8 swings to the right and thus causes a swinging movement of the maneuvering lever 86 about the joint point 85, so that the lower end of the maneuvering lever 86 is swung closer to the maneuvering element not shown, in the direction of the arrow 8 7 acting, so that the switching takes place earlier, while with the reverse regulation ring of the adjustment device, a later switching takes place.

In an advantageous embodiment of the invention, the bolt 93 is guided in a nut provided with internal thread 96, which in turn is rotatably held in place in a sliding fit 97 in the housing 46. The housing 46 is also equipped with a fixed stop 98 which projects up to the same height as the setting wheel 94. The stop 98 interacts with a projection 99 which is firmly connected to the setting wheel 94. The main way of working is as follows: For setting, the setting wheel 94 is first turned so far that the projection 99 rests against the stop 98. Then the setting wheel 94 is brought together with the bolt 93 when turning the nut 9 6 moved downwards or down towards the leg 90 of the bimetal compensation strip. In the correct, desired position, the nut 96 is fixed in relation to the housing 46, e.g. by being glued, clamped or welded.

Claims (11)

1. Contact device comprising a longitudinally displaceable pusher and, by this, movable contact pieces that interact with fixed contact pieces to form openers and/or closers, characterized in that the pusher (3 4; 59) exhibits a continuous guide across its direction of displacement ( 32, 33; 62) for a movable guide body (28; 51), that the guide body (28; 51) is placed on a coupling link (27; 53), that the coupling link (27; 53) engages in a joint manner in the area of the knee of an angle piece (16, 17; 47) that between the guide body (28; 51) and one leg (17) of the angle piece is provided with a compression spring (31; 50), that the angle piece (16, 17; 47) is pivotally supported by means of the other leg (16), and that to the movable guide body (28; 51) is assigned to a fixed guide body (29; 52) in such a way <p> g the device is arranged so that the movable guide body (28; 51) during the switching path in one direction is guided along one side and in the second direction is guided along the other side of the stationary guide body (29; 52). 2. Contact device according to claim 1, characterized in that the tension spring (31; 51) is arranged in such a way between the guide body (28; 51) and the angle piece (16, 17; 47) leg (17) that its center axis together with the center lines (55, 56) of this leg (17) and the connecting link (27; 53) in the two end positions of the switching path (10) form obtuse triangles of approximately equal size. 3. Contact device according to claim 1 or 2, characterized in that a maneuvering lever (20; 86) engages the angle piece (16, 17; 47) by means of a connecting link (21; 83) attached in an articulated manner. 4. Contact device according to one of the preceding claims, characterized in that stops (57, 58) are arranged to limit the pivoting movement of the angle piece (16, 17; 47). 5. Contact device according to claim 3 or 4, characterized in that the connecting link (83) is provided with a spring (84). 6. Contact device according to one of the preceding claims, characterized in that a return spring (24; 67) attacks the angle piece (16, 17; 47). 7. Contact device according to claim 6, characterized in that the return spring (67) with its one end is adjustably placed in an internal thread in a return spring holder (68). 8. Contact device according to one of the preceding claims, characterized in that the movable contact pieces (39, 40; 71, 77) are placed on leaf springs (41, 42; 70, 76). 9. Contact device according to one of claims 3-8, characterized in that the operating lever (86) cooperates with a compensation bimetal (89, 90). 10. Contact device according to claim 9, characterized in that the compensation bimetal (89, 90) is designed with an angular shape, is pivotably secured in a holder and with one leg (89) rests against the operating lever (86) and with the other leg (90) against an adjustment device (93, 94). 11. Contact device according to claim 10, characterized in that the adjustment device consists of a setting wheel (94) with a bolt (93) and a nut (96), that the housing (46) is provided with a stop (98) and the setting wheel (94) with a projection (99), and that the nut (96) is held in place in a sliding fit (97) in the housing (46).